Method and apparatus reduced switch-on rate low dropout regulator (LDO) bias and compensation

1. A reduced switch-on slew low dropout (LDO) regulator, further comprising: a pass gate, configured to controllably couple a voltage rail to a regulator output, the control being based in part on a pass gate control signal; a controllable slew differential amplifier, switchable between a slew-limiting state and a full-slew state, the controllable slew differential amplifier being configured to receive a feedback from the regulator output, and to generate the pass gate control signal, based on a reference voltage and the feedback, at a full-slew rate in the full-slew state, and at a reduced slew rate in the slew-limiting state; a pass gate disabling circuit, configured to selectively over-ride the pass gate control signal and switch the pass gate OFF; a switchable tail current source, coupled to the controllable slew differential amplifier, configured as switchable between sourcing a slew-limiting bias current and sourcing a full-slew bias current, and comprising a switchable full-slew bias current source and a slew-limiting bias current source, the switchable full-slew bias current source being configured to source the full-slew bias current when ON, the slew-limiting bias current source being in parallel with the switchable full-slew bias current source and configured to source the slew-limiting bias current; and a tail current control circuit, configured to switch OFF the switchable full-slew bias current source in response to an ON-to-OFF transition of a system ON-OFF signal (ST_ON/OFF) and, at a delay DLY after an OFF-to-ON transition of ST_ON/OFF, to switch ON the switchable full-slew bias current source.

2. The reduced switch-on slew LDO regulator of claim 1 , wherein the LDO regulator is configured to generate the pass gate control signal at the full-slew rate when biasing a transistor with the full-slew bias current, and at the reduced slew rate when biasing the transistor with the slew-limiting bias current.

3. A The reduced switch-on slew low-dropout (LDO) regulator, further comprising a pass gate, configured to controllably couple a voltage rail to a regulator output, the control being based in part on a pass gate control signal; a controllable slew differential amplifier, switchable between a slew-limiting state and a full-slew state, the controllable slew differential amplifier being configured to receive a feedback from the regulator output, and to generate the pass gate control signal, based on a reference voltage and the feedback, at a full-slew rate in the full-slew state, and at a reduced slew rate in the slew-limiting state; a pass gate disabling circuit, configured to selectively over-ride the pass gate control signal and switch the pass gate OFF; a switchable tail current source, coupled to the controllable slew differential amplifier, and configured as switchable between sourcing a slew-limiting bias current and sourcing a full-slew bias current; and a tail current control circuit, configured to switch the switchable tail current source to the slew-limiting bias current in response to an ON-to-OFF transition of a system ON-OFF signal (ST_ON/OFF) and, at a delay (DLY) after an OFF-to-ON transition of ST_ON/OFF, to switch the switchable tail current source from the slew-limiting bias current to the full-slew bias current.

4. The reduced switch-on slew LDO regulator of claim 3 , wherein the controllable slew differential amplifier is further configured to slew, in response to the OFF-to-ON transition of ST_ON/OFF, from an initial zero voltage to approximately Vref, at a slew rate slewing from the initial zero voltage to approximately Vref in a time duration approximately equal to DLY.

5. The reduced switch-on slew LDO regulator of claim 4 , wherein the tail current control circuit includes a delay capacitor, and a charging circuit, the charging circuit being configured to charge the delay capacitor in response to the OFF-to-ON transition of ST_ON/OFF, from a zero voltage to a tail current source mode switch threshold, in a charging time having a duration approximately equal to DLY.

6. The reduced switch-on slew LDO regulator of claim 5 , wherein the charging circuit includes a trigger switch, the trigger switch being coupled to a charging current source.

7. A reduced switch-on slew low-dropout (LDO) regulator, further comprising: a pass gate, configured to controllably couple a voltage rail to a regulator output, the control being based in part on a pass gate control signal; a controllable slew differential amplifier, switchable between a slew-limiting state and a full-slew state, the controllable slew differential amplifier being configured to receive a feedback from the regulator output, and to generate the pass gate control signal, based on a reference voltage and the feedback, at a full-slew rate in the full-slew state, and at a reduced slew rate in the slew-limiting state; a pass gate disabling circuit, configured to selectively over-ride the pass gate control signal and switch the pass gate OFF; a pass gate control line, the pass gate control line being configured to carry the pass gate control signal to a control gate of the pass gate, the pass gate disabling circuit comprising a two-position switch, the two-position switch having a disabling position and an operational position; a feedback element, coupled to the regulator output and to an input of the controllable slew differential amplifier, in a configuration to provide said feedback; and a compensation network, configured to couple the pass gate control line to the feedback element, the compensation network having a compensation capacitor and a compensation resistor, the pass gate disabling circuit being further configured to charge the compensation capacitor when the two-position switch is in the disabling position, and to allow the compensation capacitor to discharge the pass gate control line, to a voltage at which the pass gate is operational, in response to switching the two-position switch from the disabling position to the operational position, and the disabling position providing a short of the control gate to a voltage disabling the pass gate, and the operational position not providing the short of the control gate, the two-position switch being configured to switch between the disabling position and the operational position based on an ON-OFF state of ST_OFF/ON.

8. The reduced switch-on slew LDO regulator of claim 7 , wherein a rate of the reduced slew rate is based, at least in part, on at least one of a capacitance of the compensation capacitor or a resistance of the compensation resistor, or both.

9. The reduced switch-on slew LDO regulator of claim 8 , wherein the controllable slew differential amplifier includes a switchable tail current source, the switchable tail current source being configured as switchable between sourcing a slew-limiting bias current and a full-slew bias current, the controllable slew differential amplifier being configured to generate the pass gate control signal at the full-slew rate with the full-slew bias current, and at the reduced slew rate with the slew-limiting bias current, and the rate of the reduced slew rate being further based, at least in part, on the slew-limiting bias current and at least one of the capacitance of the compensation capacitor or the resistance of the compensation resistor, or both.

10. The reduced switch-on slew LDO regulator of claim 9 , further comprising a tail current control circuit, the tail current control circuit being configured to switch the switchable tail current source to the slew-limiting bias current in response to an ON-to-OFF transition of a system ON-OFF signal (ST_ON/OFF) and, at a delay DLY after an OFF-to-ON transition of ST_ON/OFF, to switch the switchable tail current source from the slew-limiting bias current to the full-slew bias current.

11. The reduced switch-on slew LDO regulator of claim 10 , the controllable slew differential amplifier being configured to slew, in response to the OFF-to-ON transition of ST_ON/OFF, from an initial zero voltage to approximately Vref, at a slew rate slewing from the initial zero voltage to approximately Vref in a time duration approximately equal to DLY.

12. The reduced switch-on slew LDO regulator of claim 11 , wherein the tail current control circuit includes a capacitor and a charging current source, the charging current source being configured to charge the capacitor from a zero voltage to a tail current source mode switch threshold in a charging time duration approximately equal to DLY.

13. A method for reduced switch-on slew low dropout (LDO) regulating with a pass gate controlled by a differential amplifier having differential inputs, and a transistor controlled by one of the differential inputs, comprising: biasing the transistor with a full-slew bias current; providing to the differential inputs a reference voltage and a feedback, the feedback being of an output of the pass gate; in response to an ON-to-OFF transition of a system on/off signal (ST_ON/OFF), disabling the feedback and switching to biasing the transistor with a slew-limiting bias current, the slew-limiting bias current being lower than the full-slew bias current; in response to an OFF-to-ON transition of ST_ON/OFF, enabling the feedback; and at a time delayed from the OFF-to-ON transition of ST_ON/OFF by a reduced slew duration, switching to biasing the transistor with the full-slew bias current.

14. The method of claim 13 , wherein the switching to biasing the transistor with the full-slew bias current includes commencing, in response to the OFF-to-ON transition of ST_ON/OFF, a charging of a delay capacitor and, in response to a voltage of the delay capacitor reaching a given threshold voltage level, performing the switching to biasing the transistor with the full-slew bias current.

15. The method of claim 13 , wherein biasing the transistor with the full-slew bias current comprises: generating, in response to the ON state of ST_ON/OFF, a biasing current source control signal at an ON level, and controlling a current source coupled to the transistor based on the biasing current source control signal at the ON level.

16. The method of claim 15 , wherein switching to biasing the transistor with the slew-limiting bias current comprises: generating, in response to the ON-to-OFF transition of ST_ON/OFF, the biasing current source control signal at an OFF level; and controlling the current source coupled to the transistor based on the biasing current source control signal at the ON level.

17. The method of claim 16 , wherein the switching to biasing the transistor with the full-slew bias current includes commencing, in response to the OFF-to-ON transition of ST_ON/OFF, a charging of a delay capacitor and, in response to a voltage of the delay capacitor reaching a given voltage level, performing the switching to biasing the transistor with the full-slew bias current.

18. A reduced switch-on slew low dropout (LDO) regulator comprising: a differential amplifier, the differential amplifier having difference inputs, an output, and a transistor, the transistor having a gate coupled to one of the difference inputs; a pass gate, configured as being controlled by the output of the differential amplifier, the pass gate having a pass gate input and a pass gate output, the pass gate input being configured to couple to a power rail, and; means for receiving a system ON/OFF signal (ST_ON/OFF) and, in response to an OFF-to-ON transition of ST_ON/OFF, establishing a feedback, the feedback being from the pass gate output to one of the difference inputs, and biasing the transistor with a full-slew bias current, and in response to an ON-to-OFF transition of ST_ON/OFF, disabling the feedback and switching to biasing of the transistor with a slew-limiting bias current.